DE69415259T2 - High voltage switch for interrupting fault currents with delayed zero crossings - Google Patents

Abstract

The present invention relates to a high-voltage circuit breaker capable of cutting off alternating fault currents with pseudo-period T and with delayed zero crossing, passing through zero after a maximum length of time tzmax-t0 after the instant t0 at which the fault appears, this length of time tzmax-t0 being determined by simulations or by trials, comprising a plurality of cutoff chambers (1) in series equipped with means for being opened at an instant t1 subsequent to the instant of the fault t0 and with means of blowing of the arc designed to operate between the instant t1 and an instant tc prior to the instant tzmax-T. It includes means for reducing the blowing throughput which are adapted so that the blowing is prolonged up to an instant t2 lying between tzmax-T and tzmax+T. <IMAGE>

Description

The present invention relates to a high-voltage interrupter capable of interrupting fault currents with a delayed zero crossing.

More specifically, it relates to a high-voltage circuit breaker capable of interrupting faulty alternating currents with pseudo-period T and delayed zero crossing, which pass through 0 after a maximum time interval tzmax - t0 after the time t0 of occurrence of a fault current, the time interval tzmax - t0 being determined by simulations or tests, comprising a plurality of separation chambers in series, provided with means for opening at a time t1 after the time of fault t0 and with means for blowing out the arc, designed to operate between the time t1 and a time tc before the time tzmax-T.

The interruption of currents with a large direct current component or with a delayed zero crossing, which are encountered, for example, in high-voltage alternating current networks with The failure of the serial compensation when certain types of faults occur poses significant problems. The presence of the direct current component can lead to the current not passing through zero during several pseudo-periods. It is then impossible to interrupt the current using conventional sulphur hexafluoride interrupters.

It is known that these problems can be solved by increasing the arc voltage by suitable means. A high arc voltage allows the energy of the direct current component of the current to be absorbed and to tend towards zero.

For this purpose, it was proposed in French patent document No. 2 681 724 to use a separation chamber provided with means for generating several arcs in series.

French patent document No. 2 678 770 also proposes using a separation chamber with permanent fuses in series with a conventional high-voltage separation chamber. The melting of the fuses during a tripping operation following a fault generates a very high arc voltage which causes the direct current component of the fault current to decrease rapidly.

It is also known to absorb the energy given by the direct current component of the network by temporarily inserting a resistance into the circuit. A suitable resistance allows this direct current component to tend to zero in a relatively short time. Such an arrangement is described in French patent document No. 2 683 937.

It is also known that the presence of a high-capacity capacitor breaker in series with an inductance in a breaker separation chamber leads, when the breaker opens, to oscillations in the current which increase the arc voltage and cause an instability of the arc which promotes the decrease of the direct current component of the current and its passage through zero. This is the case considered in French patent document No. 2 684 486, which is considered to be the closest prior art.

These solutions require the use of novel devices. The aim of the present invention is to solve the problem of interrupting fault currents with delayed zero crossing using conventional isolation chambers alone. The interrupter according to the invention only requires a particularly simple modification of the control device.

According to the invention, the interrupter comprises means for reducing the blowing flow rate, which are arranged so that blowing is continued until a time t2 between tzmax - T and tzmax + T.

This arrangement has the advantage that it does not require an intelligent device to detect the fault current and that it is completely automatic.

Preferably, the time t2 is substantially equal to tzmax.

For practical reasons, the time t2 - t0 is essentially equal to seven pseudo-periods.

In the case where the blow-out means are constituted by a piston cooperating by relative movement with a mobile device carrying a mobile arc contact and subjected to a normal opening movement at a normal opening speed defined by the normal operating conditions, the blow-out means are Reducing the blowing flow rate Means for slowing down the moving device beyond a threshold d of its normal movement.

Preferably, the threshold d is between 2D/3 and D, where D is the total normal travel of the movable device.

Advantageously, the deceleration is carried out at a constant speed.

In the case of a breaker with a hydraulic cylinder that drives the moving device and comprises a piston connected to a damping cone that cooperates with a ring, the slowing down means advantageously consist of a cylindrical portion arranged between the piston and the cone, the ring being regulated to create a certain radial clearance between it and the cylindrical portion.

The invention is described in more detail below with the aid of figures which merely represent a preferred embodiment of the invention.

Fig. 1 is a graph showing the variations of an alternating current with delayed zero crossing,

Fig. 2 is a partial longitudinal sectional view of a conventional circuit breaker.

Fig. 3 is a graph representing the movement of the movable arc contact of a breaker according to the invention according to a first variant as a function of time.

Fig. 4 is a graph representing the movement of the movable arc contact of a breaker according to the invention according to a second variant as a function of time.

Figure 5 is a longitudinal section view of the end of a hydraulic cylinder comprising means for slowing down according to the invention.

The oscillogram in Fig. 1 shows the fault current with the delayed zero crossing. The time is plotted on the abscissa and the strength of the current on the ordinate.

The fault current occurs at time t0 and helps to delay the subsequent zero crossing until a certain point in time. Such behaviors are determined by tests and/or simulations, and it is therefore possible to determine the maximum time interval before the zero crossing and thus the time tzmax of this zero crossing for a given network and the foreseen fault currents.

When the fault current occurs at time t0, the command to open the circuit breaker is given and the latter opens at time t1.

A separation chamber of a breaker according to the invention, capable of interrupting such fault currents, is shown in Fig. 2. It is a conventional chamber containing, in an insulating casing 10, the separation elements comprising a first metal tube 2 forming the main fixed contact and a second tube 3 coaxial with the first and forming the arc fixed contact. These two contacts are connected to a first power terminal. The casing is filled with a gas with good dielectric properties, such as sulphur hexafluoride, under a pressure of a few bars.

The movable device comprises a metal tube 4 extended by a discharge protection cap 5 and provided with a transverse metallic partition 8, which carries contact fingers 6 forming the main movable contact, and a blowing tube 7 which is extended by contact fingers 8 forming the arc movable contact. Holes are broken into the partition 8 for the passage of the blowing gas, and it carries a blowing nozzle 9 made of insulating material. Blowing is ensured by a stationary piston 11 arranged inside the tube 4. This tube 4 is connected to a second power connection.

The interrupter comprises a plurality of such separation chambers per phase.

The movement of the movable device is defined in the graphs shown in Figs. 3 and 4.

The series-connected separation chambers are provided with means for opening at a time t1 after the time t0 of the fault and with means for blowing out the arc operating between the time t1 and a later time.

In a conventional manner, the movable device is subjected to a normal opening movement at a normal opening speed defined by the normal operating conditions, and this movement is at the time tc shown in the figures. According to the invention, the movement of the movable device is modified from a threshold d of its normal movement so that it ends at the time t2 which lies between tzmax - T and tzmax + T, advantageously t2 being substantially equal to tzmax.

According to the first variant shown in graph 3, the threshold d is preferably between 2D/3 and D. At this threshold d, the moving device is slowed down to a substantially constant speed so that it reaches the total path D at time t2.

According to the second variant shown in Fig. 4, the threshold d is equal to the total opening path D. The total path D' is then increased and greater than D. Intermediate variants are also conceivable in which the deceleration speed and/or the total path of the movable device is changed.

Under such conditions, when the contacts open at time t1, an arc is created between the arcing contacts 3, 8 and in the case of a normal fault, this is blown out by the blowing gas in the conventional way. If the fault has a delayed zero crossing and the blowing continues until time t2, which is the worst case , the arc can also be blown out.

Investigations of experiments and simulations have shown that in practice the time t2 is preferably equal to 110 ms.

According to all possible variants, the modification of the movement of the movable device can be realized in different ways.

The preferred embodiment of the means for slowing down the movable device, in which it is moved by means of a hydraulic cylinder, is shown in Fig. 5.

This figure shows the hydraulic cylinder in the release position, that is to say in the position of opening the contacts. The piston 20 of the cylinder is at the end of its travel. To reach this position, the opening command has been transmitted by a control coil, which has led to the discharge of a pressurized fluid through the shut-off valve 21. The slide valve 22, released from the pressure of the slide 23, has thus moved (in the figure) to the right under the action of its return spring 24. It has thus blocked the passage of the pressurized oil through the Channel 25 is closed and the pressure oil which held the piston 20 in a high position corresponding to the closed position of the contacts has flowed out through the channel 26 released by the slide 23.

In a conventional manner, the piston 20 is equipped with a damping cone 27 which, during opening, cooperates with a ring 28 mounted in its recess with a longitudinal clearance and also having a radial clearance. This arrangement has the function of slowing down the piston 20 along the curve A of Fig. 3 or 4 at the end of the opening movement. The clearance of the ring 28 allows, on the one hand, its self-adjustment around the cone 27 and, on the other hand, the passage of the oil between it and the cone 27.

The deceleration means according to the invention consist of a cylindrical portion 29 arranged between the piston 20 and the cone 27 and preferably integral with the latter. This cylindrical portion 29 has a length of 1. The ring 28 is adjusted to obtain a certain radial clearance j between it and the cylindrical portion 29.

Thus, when opening, the movement of the contacts is initially controlled in the conventional manner by the cone 27 along the Curve section A is slowed down and then, depending on the selected clearance j, to a constant speed taking into account the selected clearance j and during a time t2 to tc taking into account the selected length 1 along the straight line section B shown in Fig. 3 or 4.

The application of the invention therefore requires a minimal adaptation of an existing breaker.

This adaptation is particularly minor for the application of the invention according to the curve of Fig. 3. It is then sufficient to install the damping cone 27 provided with the cylindrical region 29 on the existing piston 20, the frame 30 then having to be extended.

In case of applying the curve of Fig. 4, the path of the piston 20 must also be lengthened, and consequently also its rod and the chamber 31.

Several separation chambers can be used depending on the characteristics of the network. In practice, at least four chambers can be provided. For example, four chambers will be provided on a line with a voltage of 800 kV.

No intelligent device is required to detect the different phases of the fault current and the isolating chambers operate normally in two cycles when opening.

Claims (7)

1. High-voltage circuit breaker capable of interrupting fault alternating currents with pseudo-period T and delayed zero crossing, which pass through 0 after a maximum time interval tzmax - t0 after the time t0 of occurrence of a fault current, the time interval tzmax - t0 being determined by simulations or tests, comprising a plurality of separation chambers (1) in series provided with means for opening at a time t1 after the time of fault t0 and with means for blowing out the arc designed to operate between the time t1 and a time tc before the time tzmax - T, characterized in that it comprises means for reducing the blowing flow rate arranged so that the blowing continues until a time t2 between tzmax - T and tzmax + T. 2. Interrupter according to claim 1, characterized in that the time t2 is substantially equal to tzmax. 3. Interrupter according to one of the preceding claims, characterized in that the time t2 - t0 is essentially equal to 7 pseudo-periods. 4. Interrupter according to one of the preceding claims, in which the blowing means are formed by a piston (11) cooperating by relative movement with a mobile device carrying a mobile arc contact (8) and subjected to a normal opening movement with a normal opening speed defined by the normal operating conditions, characterized in that the means for reducing the blowing flow rate are means for slowing down the mobile device from a threshold d of its normal movement. 5. A circuit breaker according to claim 4, characterized in that the threshold d is between 2D/3 and D, where D is the total normal travel of the movable device. 6. Interrupter according to claim 4 or 5, characterized in that the slowing down is carried out at a constant speed. 7. Interrupter according to claim 6, with a hydraulic cylinder which moves the movable device and comprises a piston (20) connected to a damping cone (27) cooperating with a ring (28), characterized in that the means for slowing down consist of a cylindrical portion (28) arranged between the piston (20) and the cone (27), the ring (28) being regulated in order to produce a certain radial play between it and the cylindrical portion (29).